Fine mesh screening

ABSTRACT

A screening system having a resiliently mounted frame with a screen extending thereacross. The frame is vibrated by a low frequency vibratory drive using eccentric weights. About the peripheral frame of the screen, a high frequency drive or drives is employed to vibrate the screen in the range of 20,000 Hz. The high frequency vibration is generated at the peripheral frame about the screen. The screen is responsive to the high frequency vibrations in a plate-like manner rather than as a membrane.

This is a continuation of U.S. patent application Ser. No. 08/407,587, filed Mar. 20, 1995, issued as U.S. Pat. No. 5,542,548; which is a continuation of U.S. patent application Ser. No. 08/094,850, filed Jul. 20, 1993, issued as U.S. Pat. No. 5,398,816.

BACKGROUND OF THE INVENTION

The field of the present invention is fine mesh screening systems including the use of high frequency vibration.

Traditional vibratory screening structures typically include a base, a frame resiliently mounted on the base with a screen or screens extending across the frame. A low frequency vibratory drive in the speed range of 8 Hz to 30 Hz is mounted to the frame with eccentric weights. Specific vibratory motions are established in the frame by the low frequency vibratory drive, generating screen accelerations up to the 7 g range.

The foregoing devices have been used for screening fine materials and powders. Stainless steel woven mesh screens having interstices in the 30 to 150 micron range are used for such commercial processing. These delicate, woven meshes are typically thin and comparatively limp. The mesh is usually stretched tightly and attached to a screen frame. The vibration of such devices typically enhances gravity separation of particles presented to the screen. Where fine particles are to be screened, the vibration also has a deleterious effect in that the fine particles become suspended above a boundary layer over the vibrating screen.

Fine mesh screens can be reasonably fragile under many if not most applications. Backing screens and perforated plates have been used to help support such screens. Such supported screens may be bonded or unbonded. One type of area bonding is diffusion bonding. In some instances, a fine screen cloth, a coarse screen cloth and a perforated plate have been used. The separate layers are bonded by heat and pressure into a unitary structure. A frame is typically used about the periphery of the composite screen structure for support, mounting and screen tension.

In an effort to overcome the deficiency of low frequency vibration, high frequency vibration has been employed. Ultrasonic vibrators have been mounted to separator frames with a direct mechanical attachment to the screens at the centers thereof. Alternatively, ultrasonic drives have been bonded directly to the screen. Fine mesh, tensioned screens tend to suffer fatigue failure at the boundary layer with the mechanical coupling to the ultrasonic drive and to dissipate energy within a few inches of that coupling. Such devices also use low frequency vibratory drives, principally as a means for conveying material across the screen or screens.

SUMMARY OF THE INVENTION

The present invention is directed to screening systems using a resiliently mounted frame with a low frequency drive mounted to the frame and a high frequency drive rigidly associated with a screen with the screen and the high frequency drive resiliently supported relative to the frame. The vibratory frame driven at low frequencies is, therefore, not directly and rigidly fixed to the high frequency drive.

In certain and separate aspects of the present invention, brackets or supports are specifically contemplated. Other structural details may also be optionally included in certain separate aspects of the invention.

Thus, improved fine particle screening is achieved. Other objects and advantages will appear hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an elevation of a vibratory separator employing high frequency drives.

FIG. 2 is a cross-sectional detail of a separator illustrating a first mounting of a high frequency drive.

FIG. 3 is a cross-sectional detail illustrating a second mounting of a high frequency drive.

FIG. 4 is a cross-sectional detail of a second embodiment showing a first transducer mounting and an isolated frame.

FIG. 5 is a cross-sectional detail of a second embodiment showing a second transducer mounting and an isolated frame.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Turning in detail to the drawings, FIG. 1 illustrates a vibratory screen separator. The separator includes a base 10 resiliently mounting a separator frame 12 by means of springs 14. The separator frame 12 is illustrated here to be cylindrical, open at the top to receive material input and having discharge ports 16 and 18 for the screened material and the oversize material, respectively. A low frequency vibratory drive 20 is rigidly fixed to the separator frame 12. The drive 20 includes upper and lower eccentric weights 22 and 24 to generate a vibratory motion when rotatably driven.

A screen 26 extends across the separator frame 12 such that material input above the screen 26 must either pass through the screen or through the oversize discharge port 18. The screen 26 includes a screening element 28 stretched in tension uniformly by a screen frame 30. In the preferred embodiments, the screening element 28 is a composite of a fine mesh screen of a desired size with a stiffer porous sheet, most conveniently a perforated plate. Diffusion bonding is employed across the full area of the screening element 28. Such bonded screening elements are commercially available.

To properly bond fine mesh screen cloth to a perforated plate with diffusion bonding, it is preferable to include a coarse mesh screen cloth therebetween. A fine mesh screen 32, a coarse mesh screen 34 and a perforated plate 36 are shown. These are supplied as a diffusion bonded laminate which is tensioned and bonded to a screen frame 30 to form the screen structure 26. The fine mesh screen cloth may be dictated by the requirements of the materials being screened. 200 mesh and 325 mesh screen cloth is common. The backing perforated plate is preferably 80% open and is from 1/16" to 3/16" thick. Design choice may dictate thinner or thicker plates depending on separator size, weight of material, degree of low frequency vibrations and the like.

In vibration theory, one might attempt to analyze vibration of a thin planar object as either a membrane where the tension forces in the plane of the object dominate or as a plate where resistance to bending, or stiffness, of the planar object dominates. The propagation constant or wavenumber for membrane vibration is: ##EQU1## where λ=wavelength

ω=frequency radians per second

C=velocity of waves

ρ=mass density

T=static tension

The wavenumber for a plate is: ##EQU2## where D=plate bending stiffness= ##EQU3## E=Young's Modulus h=thickness of the plate

ν=Poisson's ratio.

To determine appropriate screen characteristics, the relative effects of stiffness and tension may be determined by calculating the ratio of the two wavenumbers: ##EQU4## When this ratio is much less than unity, tension dominates and membrane theory applies. When the ratio is much greater than unity, stiffness dominates; therefore, the screen behaves in a plate-like manner. Using this formula, screens exhibiting a ratio in excess of unity tend to act plate-like while screens exhibiting a ratio of less than unity tend to act membrane like. In estimating plate bending stiffness, the standard Poisson's ratio for stainless steel may be reduced to 0.2 to account for the relief provided by the holes in the screen. Calculations of unsupported and supported screens at a vibration frequency of 20,000 Hz establish the following values:

    ______________________________________                 Mass      Plate      Wavenumber                 Density,  Stiffness, Ratio     Screen      ρ, g/m.sup.3                           D, newton-mm                                      (Eq. 4)     ______________________________________     200 mesh    298       0.38       0.67     325 mesh    209       0.19       0.51     200 mesh bonded                 696       13.3       2.02     325 mesh bonded                 611       11.6       1.88     ______________________________________

In running a test unit, using an 18 inch diameter 200 mesh (74 micron) diffusion bonded screen having the properties as indicated in the table, excitation frequency was set at approximately 20,000 Hz. One hundred watts of power was employed which appears to have been more than sufficient. Increasing the wattage did not appear to significantly increase screening efficiency. Screening efficiency may in fact increase with decreased wattage and adjustment of the vibration pattern. Effective high frequency vibration is understood to be in the range of from about 10,000 Hz to 50,000 Hz. The plate-like behavior of the screen has suggested that less tension may be necessary as well.

Empirical results suggest close to double the screening efficiency of the same system without high frequency vibration. One or more high frequency generators 38 are associated with the peripheral frame. Clearly, empirical testing as to the number of generators 38, their placement and orientation for the characteristics of each material being processed is appropriately conducted. An increased number of generators 38 provides greater flexibility and uniformity of high frequency energy coverage. However, increasing the number of generators 38 increases cost and complexity. Several types of such generators are available. It is presently believed that magnetostrictive ultrasonic transducers with internal feedback control are preferred as they are more rugged for shop use and have a wider frequency band.

As illustrated in FIGS. 2 through 5, two types of screen mountings are employed. In FIGS. 2 and 3, the separator frame 12 directly supports the screen 26. The high frequency generator 38 is shown to be mounted rigidly to the separator frame 12 by a fixed bracket 40. The action of the high frequency generator or generators 38 through the fixed bracket or brackets 40 on the separator frame 12 is transferred from that peripheral frame to the screen 26. The separator frame 12 in its entirety is also subject to be vibrated in this arrangement.

An alternative arrangement is illustrated in FIGS. 4 and 5. In these figures, resilient elements or gaskets 42 and 44 are positioned on top and bottom of the screen frame 30 to isolate the screen frame from the surrounding separator frame 12. The resilient elements would act to isolate the separator frame 12 but would also act to damp some of the power generated by the generator(s) 38. Again, the vibration is introduced by means of a peripheral frame to the screen 26.

Low frequency vibration is employed at levels allowing the separator frame 12 and screen 26 to vibrate as a rigid body, even in the embodiment where the resilient elements 42 and 44 are employed. Smaller power and lighter weights may be employed for the low frequency vibratory drive as compared with conventional low frequency separators since this drive is now relegated to transportation of material across the screen. Low frequency vibrations effective for conveying material are typically considered most effective in the 3 Hz to 30 Hz range. Energy typically effective for conveyance of fine material on a screen may be measured in screen acceleration in the 1/2 g to 4 g range at 20 Hz.

Accordingly, an improved fine mesh screening system is disclosed. While embodiments and applications of this invention have been shown and described, it would be apparent to those skilled in the art that many more modifications are possible without departing from the inventive concepts herein. The invention, therefore is not to be restricted except in the spirit of the appended claims. 

What is claimed is:
 1. A screening system comprisinga resiliently mounted frame; a low frequency vibratory drive coupled to the frame; a screen extending across the frame; a high frequency drive rigidly coupled with the screen; and a resilient mounting on the frame, the screen being supported by the resilient mounting on the frame and the high frequency drive being solely supported by the resilient mounting on the frame and displaced from the frame.
 2. The screening system of claim 1, the resilient mounting being a gasket.
 3. The screening system of claim 1, further comprisinga bracket mounted to the resilient mounting and coupled to the screen and supporting the screen.
 4. The screening system of claim 3, the screen including a periphery with a screen frame, the bracket being coupled to the screen frame at the periphery.
 5. The screening system of claim 1, further comprisinga bracket mounted to the resilient mounting and coupled to the screen, and to the high frequency drive.
 6. The screening system of claim 5, the bracket being rigidly coupled to the screen and the high frequency drive.
 7. The screening system of claim 6, the bracket being the support for the screen.
 8. The screening system of claim 7, the high frequency drive being outwardly of the frame.
 9. The screening system of claim 1, the screen being stiffened as to bending to have predominantly plate-like properties as measured at 20,000 Hz.
 10. The screening system of claim 9, the high frequency drive having a range of vibration above about 10,000 Hz.
 11. The screening system of claim 1 further comprisingmultiple said high frequency drives.
 12. A screening system comprisinga resiliently mounted frame; a low frequency vibratory drive coupled to the frame; a screen extending across the frame; a bracket rigidly fixed to the screen; a high frequency drive mounted solely to the bracket to vibrate the screen above about 10,000 Hz and displaced from the frame; and resilient mounting between the bracket and the resiliently mounted frame.
 13. The screening system of claim 12 further comprising multiple high frequency drives. 